Image display apparatus

ABSTRACT

An image display apparatus that displays an image by scanning of coherent light includes: a light source portion that emits the coherent light; a scanning portion that scans the coherent light; a concave reflection portion having a concave surface from which the coherent light is reflected; and an incident position changing unit that changes an incident position of the coherent light onto the concave surface in a curvature direction of the concave surface.

BACKGROUND

1. Technical Field

The present invention relates to an image display apparatus and inparticular, to a technique of an image display apparatus that displaysan image using a laser beam.

2. Related Art

A technique of using a laser light source as a light source of an imagedisplay apparatus, such as a projector, has been recently proposed. Ascompared with a UHP lamp that has been used as a light source of aprojector in the related art, the laser light source is advantageous inhigh color reproducibility, instant lighting, a long life, and the like.Moreover, since loss of energy is low and luminous efficiency is highcompared with the UHP lamp, it is also considered that the laser lightsource is effective in reducing the power consumption of the imagedisplay apparatus.

An example of an image display apparatus that uses a laser light sourceincludes an image display apparatus that displays an image by scanning alaser beam, which is coherent light, with a light scanning device andmaking the laser beam irradiated onto an irradiated surface, such as ascreen. When the laser beam is irradiated onto the irradiated surface,an interference pattern called a speckle pattern in which bright pointsand dark points are randomly distributed may appear.

The speckle pattern is a dynamic brightness pattern (also called aspeckle noise) occurring due to random interfere of light beams diffusedat points of a diffused surface. Since the speckle pattern is recognizedas fine particle shaped glare to human eyes, the speckle pattern greatlylowers the display quality of an image. For this reason, it is necessaryto take measures against the speckle noise in case of using a laserlight source.

In order to reduce the speckle noise, for example, InternationalPublication No. 2005/078519 pamphlet proposes a technique of rocking anoptical path of a laser beam irradiated onto an irradiated surface. Inthe technique proposed in International Publication No. 2005/078519pamphlet, the speckle noise is reduced by shifting irradiated positionsof laser beams on the irradiated surface by rocking of the optical pathso that a plurality of speckle patterns are superimposed.

However, when the irradiated positions of laser beams on the irradiatedsurface are shifted, the image may be recognized as a vibrating image ora blurred image due to the shift. As a result, the display quality ofthe image may lower on the contrary.

SUMMARY

An advantage of some aspects of the invention is that it provides animage display apparatus capable of effectively reducing a speckle noiseand displaying a high-quality image by changing a speckle pattern whilesuppressing deviation of an irradiated position of a laser beam on anirradiated surface.

According to an aspect of the invention, an image display apparatus thatdisplays an image by scanning of coherent light includes: a light sourceportion that emits the coherent light; a scanning portion that scans thecoherent light; a concave reflection portion having a concave surfacefrom which the coherent light is reflected; and an incident positionchanging unit that changes an incident position of the coherent lightonto the concave surface in a curvature direction of the concavesurface.

The curvature direction of the concave surface is a direction in whichthe curvature of the concave surface is given. As the incident positionchanges in the curvature direction of the concave surface, an angle ofreflection of coherent light also changes. By changing the incidentposition of the coherent light onto the concave surface, the incidentangle of the coherent light onto the irradiated surface, such as ascreen, is changed. The change in the incident angle of coherent lightgenerates a plurality of speckle patterns. By making the plurality ofspeckle patterns superimposed on a viewer's retina, a specific specklepattern cannot be recognized and a speckle noise can be reduced.

In addition, coherent light components reflected at different positionsof the concave surface can be concentrated on the irradiated surface bymaking the reflecting surface as a concave surface. By making thecoherent light concentrate on the irradiated surface, the incident angleof light onto the irradiated surface is changed without almost changingthe irradiated position of the coherent light onto the irradiatedsurface. That is, by changing a speckle pattern while suppressingdeviation of an irradiated position of a laser beam on an irradiatedsurface, it is possible to effectively reduce the speckle noise and todisplay a high-quality image.

Furthermore, in the image display apparatus according to the aspect ofthe invention, it is preferable that the incident position changing unitbe a light source moving unit that moves the light source portion. Theincident position of the coherent light onto the concave surface ischanged with a configuration of moving a light source. Accordingly,since a new optical element for changing the incident position ofcoherent light is not needed, the configuration becomes simple.

Furthermore, in the image display apparatus according to the aspect ofthe invention, it is preferable to further include a transmissionportion that is disposed on an optical path of the coherent light beforebeing incident on the concave surface and that transmits the lighttherethrough. In addition, preferably, the incident position changingunit is an inclination changing unit that changes the inclination of thetransmission portion with respect to the coherent light.

By refraction of the coherent light on the interface of the transmissionportion, the optical path shifts. Since the change in the inclination ofthe transmission portion with respect to the coherent light changes theshift amount of the optical path, the incident position of the coherentlight onto the concave surface can be changed. Since the transmissionportion changes the optical path of the coherent light using refractionof light, an electric wiring line is not required for the transmissionportion itself. Accordingly, since there is no possibility that a wiringline will be disconnected by the change in the inclination of thetransmission portion, the reliability of the image display apparatus canbe secured.

Furthermore, in the image display apparatus according to the aspect ofthe invention, it is preferable to further include a return reflectionportion that reflects the coherent light to travel to the scanningportion. In addition, preferably, the scanning portion includes theconcave reflection portion and the incident position changing unit is areturn reflection portion moving unit that moves the return reflectionportion.

Since the optical path of the coherent light traveling toward thescanning portion including the concave reflection portion shifts withmovement of the return reflection portion, the incident position of thecoherent light onto the concave surface can be changed. Since the returnreflection portion changes the optical path of the coherent light usingreflection of light, an electric wiring line is not required for thereturn reflection portion itself. Accordingly, since there is nopossibility that a wiring line will be disconnected by movement of thereturn reflection portion, the reliability of the image displayapparatus can be improved.

Furthermore, in the image display apparatus according to the aspect ofthe invention, it is preferable that the return reflection portion be adichroic mirror. The dichroic mirror has a characteristic of makinglight in a specific wavelength range reflected therefrom and light inthe other wavelength range transmitted therethrough. Accordingly, usingthe dichroic mirror, it is possible to selectively reflect only lightwith a specific color (wavelength) and irradiate the light on theirradiated surface. Since the optical path of the coherent lighttraveling toward the scanning portion including the concave reflectionportion shifts with movement of the dichroic mirror, the incidentposition of the coherent light onto the concave surface can be changed.

A plurality of dichroic mirrors may be provided. For example, blue lightand green light can be mixed by reflecting the green light from areflecting surface of a dichroic mirror that reflects the green lightand projecting the blue light from a bottom surface side of thereflecting surface. Then, by reflecting red light from a reflectingsurface of a dichroic mirror that reflects only red light and projectinglight, obtained by mixing of the blue light and the green light, from abottom surface side of the reflecting surface, three colors of red (R),green (G), and blue (B) can be mixed. As a result, a color image can bedisplayed. In addition, when a plurality of dichroic mirrors areprovided, light components corresponding to respective colors may bemixed on an irradiated surface by concentration on the irradiatedsurface even if the light components are not mixed until the lightcomponents reach the irradiated surface. Accordingly, movement periodsof the plurality of dichroic mirrors may not synchronize with eachother.

Furthermore, in the image display apparatus according to the aspect ofthe invention, preferably, the scanning portion has a first scanningportion that scans the coherent light in a first direction and a secondscanning portion that scans the coherent light in a second directionapproximately perpendicular to the first direction at a longer periodthan a period at which the coherent light is scanned by the firstscanning portion, and the second scanning portion includes the concavereflection portion.

Since the first and second directions are approximately perpendicular toeach other, an image spreading in a two-dimensional manner can bedisplayed in a predetermined region (for example, on the irradiatedsurface). The second scanning portion scans coherent light at a longerperiod than a scanning period of the first scanning portion.Accordingly, for example, when the scanning portion rocks to scan thecoherent light, the moment applied to the second scanning portion due tothe rocking decreases. As a result, since deflection of the concavesurface caused by the influence of the moment can also be reduced, thecoherent light can be concentrated with high precision.

A small member (for example, a MEMS (micro electro mechanical system)mirror) is used as the first scanning portion with a short period, atwhich coherent light is scanned, in many cases. On the other hand, alarger member (for example, a galvanomirror) than the first scanningportion is used as the second scanning portion in many cases.Accordingly, it is easy to form the concave surface in the secondscanning portion rather than the first scanning portion, and themanufacturing cost can be suppressed.

Furthermore, in the image display apparatus according to the aspect ofthe invention, preferably, the scanning portion has a first scanningportion that scans the coherent light in a first direction, a secondscanning portion that scans the coherent light in a second directionapproximately perpendicular to the first direction, and a returnreflection portion within a scanning portion that reflects the coherentlight reflected by the first scanning portion toward the second scanningportion, and the return reflection portion within a scanning portionincludes the concave reflection portion.

Since the return reflection portion within a scanning portion itself isnot related to scanning of the coherent light, it is not necessary torock the return reflection portion within a scanning portion.Accordingly, the concave surface is not bent by rocking of the returnreflection portion within a scanning portion. That is, since it can beprevented that coherent light is dispersed by bending of the concavesurface, it is possible to prevent the display quality from lowering.

A larger member than the first scanning portion or the second scanningportion is used as the return reflection portion within a scanningportion, which is not related to scanning of coherent light, in manycases. As a result, since it becomes easy to form a concave surface onthe return reflection portion within a scanning portion, themanufacturing cost can be suppressed.

Furthermore, in the image display apparatus according to the aspect ofthe invention, it is preferable that the first direction and thecurvature direction of the concave surface are approximatelyperpendicular to each other. Since the first direction and the curvaturedirection of the concave surface are perpendicular to each other, aninfluence caused by giving the curvature can be suppressed forreflection of coherent light scanned by the first scanning portion onthe concave surface. Accordingly, distortion of an image displayed onthe irradiated surface can be reduced compared with a case where thefirst direction and the curvature direction of the concave surface areparallel.

Furthermore, in the image display apparatus according to the aspect ofthe invention, preferably, the scanning portion has a first scanningportion, which scans the coherent light in a first direction, and asecond scanning portion, which scans the coherent light in a seconddirection approximately perpendicular to the first direction at a longerperiod than a period at which the coherent light is scanned by the firstscanning portion, and the first scanning portion includes the concavereflection portion.

Since the first and second directions are approximately perpendicular toeach other, an image spreading in a two-dimensional manner can bedisplayed in a predetermined region (for example, on the irradiatedsurface). As described above, a small member (for example, a MEMSmirror) is used as the first scanning portion that scans the coherentlight with a shorter period than the second scanning portion in manycases. Since the concave surface is also small if the first scanningportion is small, an influence (for example, variation in the reflectingdirection) caused by giving the curvature to the concave reflectionportion can be suppressed.

Furthermore, in the image display apparatus according to the aspect ofthe invention, it is preferable to further include a return reflectionportion that reflects the coherent light to travel to the scanningportion. In addition, preferably, the return reflection portion includesthe concave reflection portion and the incident position changing unitis a return reflection portion moving unit that moves the returnreflection portion.

The incident position of the coherent light onto the concave surface canbe made to change with the movement of the return reflection portionincluding the concave reflection portion. Since the angle of reflectionof coherent light can be made to change with the movement of the returnreflection portion, the reflected coherent light can also beconcentrated on the irradiated surface. Since the return reflectionportion changes the optical path of the coherent light using reflectionof light, an electric wiring line is not required for the returnreflection portion itself. Accordingly, since there is no possibilitythat a wiring line will be disconnected by movement of the returnreflection portion, the reliability of the image display apparatus canbe secured.

In addition, since the return reflection portion is not related toscanning of the coherent light, it is not necessary to rock the returnreflection portion. Accordingly, the concave surface is not bent byrocking of the return reflection portion. That is, since it can beprevented that coherent light is dispersed by bending of the concavesurface, it is possible to prevent the display quality from lowering.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described with reference to the accompanyingdrawings, wherein like numbers reference like elements.

FIG. 1 is a schematic view illustrating the configuration of an imagedisplay apparatus according to a first embodiment of the invention.

FIG. 2 is a perspective view illustrating a biaxial scanner.

FIG. 3 is a schematic view illustrating optical paths of laser beamsreflected from a reflecting surface.

FIG. 4 is a schematic view illustrating the configuration of an imagedisplay apparatus according to a second embodiment of the invention.

FIG. 5 is a schematic view illustrating the configuration of an imagedisplay apparatus according to a third embodiment of the invention.

FIG. 6 is a schematic view illustrating optical paths of laser beamstransmitted through a parallel plate.

FIG. 7 is a schematic view illustrating the configuration of an imagedisplay apparatus according to a fourth embodiment of the invention.

FIG. 8 is a schematic view illustrating optical paths of laser beamsreflected by return mirrors.

FIG. 9 is a schematic view illustrating the configuration of an imagedisplay apparatus according to a fifth embodiment of the invention.

FIG. 10 is a schematic view illustrating optical paths of laser beamsreflected by a return mirror.

FIG. 11 is a schematic view illustrating the configuration of an imagedisplay apparatus according to a sixth embodiment of the invention.

FIG. 12 is a schematic view illustrating the configuration of an imagedisplay apparatus according to a seventh embodiment of the invention.

FIG. 13 is a schematic view illustrating the configuration of an imagedisplay apparatus according to an eighth embodiment of the invention.

DESCRIPTION OF EXEMPLARY EMBODIMENTS

Hereinafter, embodiments of the invention will be described in detailwith reference to the accompanying drawings.

First Embodiment

FIG. 1 is a schematic view illustrating the configuration of an imagedisplay apparatus 1 according to a first embodiment of the invention.The image display apparatus 1 displays an image on an irradiated surfaceof a screen 11 by scanning a laser beam modulated according to an imagesignal. The image display apparatus 1 is configured to mainly include alight source device 12, a return mirror (return reflection portion) 4, avibrating device (incident position changing unit, return reflectionportion moving unit) 3, and a biaxial scanner (scanning portion) 14.Moreover, in the explanation of embodiments of the invention, an axisperpendicular to the screen 11 is assumed to be a Z axis. An axis thatis perpendicular to the Z axis and extends horizontally is assumed to bean X axis. In addition, an axis perpendicular to the ZX plane is assumedto be a Y axis.

The light source device 12 is configured to include a semiconductorlaser 16 (light source portion) and a collimator optical system 18. Thesemiconductor laser 16 has a function of emitting a laser beam ascoherent light toward the return mirror 4. The collimator optical system18 is provided at the position on which light emitted from thesemiconductor laser 16 is incident. The collimator optical system 18 hasa function of collimating laser beams emitted from the semiconductorlaser 16.

For modulation according to an image signal, either amplitude modulationor pulse width modulation may be used. The image display apparatus 1 haslight source devices for color light components, which correspond to red(R) light, green (G) light, and blue (B) light, and a color mixingoptical system that mixes the color light components. Here, detailedexplanations on the light source devices for color light component andthe color mixing optical system will be omitted.

The return mirror 4 has a function of reflecting a laser beam emittedfrom the semiconductor laser 16 and making the laser beam travel towardthe biaxial scanner 14. The vibrating device 3 shifts (converts) anoptical path of the laser beam emitted from the semiconductor laser 16by moving (vibrating) the return mirror 4. In the first embodiment, thevibrating device 3 has a piezoelectric element 3 a.

The piezoelectric element 3 a has a property of expanding andcontracting when a voltage is applied. The return mirror 4 is moved(vibrates) by repeated application of a voltage to the piezoelectricelement 3 a using such a property. Since the return mirror 4 vibrates, aposition of the return mirror 4 from which a laser beam is reflected onthe optical path of the laser beam changes. Accordingly, the opticalpath of the laser beam reflected by the return mirror 4 is shifted(converted) in the Z-axis direction. By shifting the laser beam, theincident position of the laser beam onto a concave surface, which willbe described later, is changed. Moreover, in the first embodiment, thevibration direction of the return mirror 4 approximately matches thenormal direction of a reflecting surface of the return mirror 4.However, the vibration direction of the return mirror 4 is not limitedthereto. For example, the vibration direction of the return mirror 4 mayapproximately match the optical path direction of a laser beam incidenton the return mirror 4 or may approximately match the optical pathdirection of a laser beam reflected by the return mirror 4. As thevibrating device 3, not only the piezoelectric element 3 a but also amotor may be used or an electrically driven vibrating device using acoil or a magnet may be used, for example.

FIG. 2 is a perspective view illustrating the biaxial scanner 14. Thebiaxial scanner 14 scans laser beams emitted from the light sourcedevice 12 in the two-dimensional direction (horizontally and vertically)on the screen 11. A biaxially movable mirror (concave reflectionportion) 20 that reflects light therefrom is disposed in the middle ofthe biaxial scanner 14. The biaxially movable mirror 20 has a functionof reflecting a laser beam, which is reflected from the return mirror 4,toward the screen 11.

The biaxially movable mirror 20 is surrounded by a first support portion22. The first support portion 22 is surrounded by a second supportportion 24. The biaxially movable mirror 20 and the first supportportion 22 are connected to each other by a first torsion spring 26. Thebiaxially movable mirror 20 rocks with the first torsion spring 26 as ashaft. The first support portion 22 and the second support portion 24are connected to each other by a second torsion spring 28. The biaxiallymovable mirror 20 rocks with the second torsion spring 28 as a shaft.The rocking direction of the biaxially movable mirror 20 using the firsttorsion spring 26 as a shaft is approximately perpendicular to therocking direction of the biaxially movable mirror 20 using the secondtorsion spring 28 as a shaft.

The biaxially movable mirror 20 rocks with reflection of a laser beam tothereby scan the laser beam in the two-dimensional direction on thescreen 11. The biaxially movable mirror 20 rocks with the first torsionspring 26 as a shaft to thereby scan a laser beam in a horizontaldirection (X-axis direction) and rocks with the second torsion spring 28as a shaft to thereby scan a laser beam in a vertical direction (Y-axisdirection). In addition, a structure of generating a driving force fordriving the biaxially movable mirror 20 is omitted. As structures fordriving the biaxially movable mirror 20, various structures including astructure driven by electrostatic driving, a structure driven byelectromagnetic driving using an electromagnetic force, and a structuredriven by using an elastic force of a piezoelectric element may beconsidered.

A reflecting surface 20 a of the biaxially movable mirror 20 is aconcave surface. The reflecting surface 20 a has a cylindrical shapewith a curvature in one of two directions perpendicular to each other.In the first embodiment, the curvature direction of the concave surfaceis the same direction as a shift direction (Z-axis direction) of a laserbeam by the operation of the vibrating device 3. Alternatively, thereflecting surface 20 a may be a spherical concave surface with acurvature in two directions perpendicular to each other. In this case,the shift direction of a laser beam may be any direction with acurvature. In addition, at least a part of the reflecting surface 20 amay be a concave surface. That is, the entire reflecting surface 20 adoes not necessarily need to be a concave surface.

FIG. 3 is a schematic view illustrating optical paths of laser beamsreflected from the reflecting surface 20 a. The optical paths of laserbeams are shifted in the Z-axis direction since the return mirror 4vibrates by an operation of the vibrating device 3. The incidentpositions of the laser beams onto the reflecting surface 20 a change inthe curvature direction of the concave surface with the shift of theoptical paths of the laser beams.

Since the reflecting surface 20 a of the biaxially movable mirror 20 isa concave surface, an angle formed by a light beam incident on thereflecting surface 20 a and a reflected light beam changes with theincident position of a laser beam. For example, the relationship amongan angle α1 formed by a light beam incident on the approximate center ofthe reflecting surface 20 a and a light beam reflected therefrom, anangle α2 formed by a light beam incident on a position shifted to oneside from the approximate center of the reflecting surface 20 a and alight beam reflected therefrom, and an angle α3 formed by a light beamincident on a position shifted to the other side from the approximatecenter of the reflecting surface 20 a and a light beam reflectedtherefrom is α2<α1<α3. Accordingly, the laser beams whose optical pathshave shifted by vibration of the return mirror 4 change the course inthe concentration direction by reflection on the reflecting surface 20a.

Furthermore, if the curvature of the reflecting surface 20 a, which is aconcave surface, is set such that laser beams approximately concentrateon a position assumed when the screen 11 is disposed, the positionaldeviation of the irradiated position of laser beams on the screen 11 canbe suppressed to the minimum. As a result, the quality of an image canbe secured. In addition, since incident angles β1, β2, and β3 of laserbeams onto the screen 11 also change, a speckle pattern occurring whenlaser beams are irradiated onto the screen 11 can be changed.Accordingly, if the vibrating device 3 is made to operate while an imageis being displayed on the screen 11, a plurality of speckle patterns canbe superimposed on a viewer's retina. As a result, the speckle noise canbe reduced. Here, the ‘position assumed when the screen 11 is disposed’means a position corresponding to the standard of a projection allowabledistance of the image display apparatus 1. For example, when apredetermined width is given for the projection allowable distance, thecurvature of the reflecting surface 20 a is set such that laser beamsapproximately concentrate on the screen 11 when the screen 11 isdisposed at a position at which the distance from the image displayapparatus 1 is approximately in the middle of the predetermined width.

In addition, when the curvature direction of the concave surface and thedirection in which a laser beam shifts are the same direction, thespeckle noise can be reduced while suppressing deviation of theirradiated position of the laser beam. In the first embodiment, theconcave surface is formed such that the curvature direction of theconcave surface is the Z-axis direction. However, the curvaturedirection of the concave surface may be any direction. By matching theshift direction of the optical path with the curvature direction,deviation of the irradiated position can be suppressed while changingthe incident angle of a laser beam onto the irradiated surface. As aresult, it is possible to secure the image quality and to reduce thespeckle noise.

Second Embodiment

FIG. 4 is a schematic view illustrating the configuration of an imagedisplay apparatus 10 according to a second embodiment of the invention.The second embodiment is characterized in that the optical path of alaser beam is shifted by vibrating a light source device 12. The sameconstituent components as in the first embodiment are denoted by thesame reference numerals, and a repeated explanation thereof will beomitted. The image display apparatus 10 is configured to mainly includethe light source device 12, a vibrating device (incident positionchanging unit, light source moving unit) 13, and a biaxial scanner(scanning portion) 14.

Since the light source device 12 has the same configuration as in thefirst embodiment, a detailed explanation thereof will be omitted. Thelight source device 12 is disposed such that a laser beam emitted from asemiconductor laser 16 moves toward the biaxial scanner 14. Thevibrating device 13 has the piezoelectric element 13 a and the likesimilar to the first embodiment, and a detailed explanation thereof willbe omitted. Vibration of the light source device 12 causes the opticalpath of a laser beam emitted from the semiconductor laser 16 to beshifted in the Z-axis direction. The shift of the laser beam changes theincident position of the laser beam onto the reflecting surface (concavesurface) 20 a of the biaxial scanner 14. In addition, the vibrationdirection of the light source device 12 is set to be the curvaturedirection of a concave surface. Therefore, similar to the firstembodiment, it is possible to prevent the image quality from lowering bysuppressing deviation of the irradiated position by concentration oflaser beams and to reduce a speckle noise by changing the incident angleof a laser beam onto the screen 11.

If the optical path of a laser beam traveling toward the reflectingsurface 20 a is shifted, deviation of the irradiated position can besuppressed while changing the incident angle of the laser beam onto thescreen 11 by the operation of the concave surface formed on thereflecting surface 20 a, similar to the first embodiment. As a result,the speckle noise can be reduced while securing the quality of an imagedisplayed on the screen 11 by concentrating laser beams on the screen11.

In the second embodiment, the optical paths of laser beams are shiftedwith a simple configuration of moving the light source device 12.Accordingly, the image display apparatus can be formed with a simpleconfiguration without adding a new optical element. On the other hand,in the image display apparatus 1 according to the first embodiment, thereturn mirror is moved to shift the optical path of a laser beam. Sincethe mirror itself has only a function of reflecting light, an electricwiring line is not required. Accordingly, since there is no possibilitythat a wiring line will be disconnected by movement of the returnmirror, the reliability of the image display apparatus can be secured.

In addition, the speckle noise can be reduced while suppressingdeviation of the irradiated position of a laser beam if the curvaturedirection of the concave surface and the shift direction of the laserbeam are the same direction. Also in the second embodiment, the concavesurface is formed such that the curvature direction of the concavesurface is the Z-axis direction. However, the curvature direction of theconcave surface may be any direction. Since deviation of the irradiatedposition can be suppressed while changing the incident angle of a laserbeam onto the irradiated surface by matching the shift direction of theoptical path with the curvature direction, it is possible to secure theimage quality and to reduce the speckle noise.

Third Embodiment

FIG. 5 is a schematic view illustrating the configuration of an imagedisplay apparatus 50 according to a third embodiment of the invention.The third embodiment is characterized in that the optical path of alaser beam is shifted (converted) by a parallel plate (transmissionportion) 53. The same constituent components as in the first embodimentare denoted by the same reference numerals, and a repeated explanationthereof will be omitted. The image display apparatus 50 is configured toinclude a light source device 12, the parallel plate 53, a rockingdevice (incident position changing unit, inclination changing unit) 56,and a biaxial scanner 14. The parallel plate 53 is located between thelight source device 12 and the biaxial scanner 14 and is disposed on anoptical path before a laser beam emitted from the light source device 12is incident on the biaxial scanner 14. The parallel plate 53 is aplate-like member formed of a transmissive material that allows light tobe transmitted therethrough. Of the parallel plate 53, an incidentsurface 53 a on which a laser beam is incident and an emission surface53 b from which the incident laser beam is emitted are parallel. When alaser beam is transmitted through the parallel plate 53, the laser beamis refracted on the incident surface 53 a and the emission surface 53 b.

FIG. 6 is a schematic view illustrating optical paths of laser beamstransmitted through the parallel plate 53. The parallel plate 53 isrotatably supported on the rocking shaft 54 that extends in a direction(X-axis direction) approximately perpendicular to the optical paths oflaser beams. In addition, the rocking device (incident position changingunit) 56 is disposed at the end of the parallel plate 53. The rockingdevice 56 has a piezoelectric element 3 a. By making the piezoelectricelement 3 a expand and contract by repeated application of a voltage tothe piezoelectric element 3 a, the end of the parallel plate 53 can bemade to reciprocate. When the end 53 c of the parallel plate 53 is madeto reciprocate by the rocking device 56, the parallel plate 53 rockswithin a predetermined angle range around the rocking shaft 54. When theparallel plate 53 rocks around the rocking shaft 54, the inclination ofthe incident surface 53 a and the inclination of the emission surface 53b with respect to a laser beam change. The change in the inclination ofthe incident surface 53 a and the inclination of the emission surface 53b shifts the optical path of the laser beam, which has been transmittedthrough the parallel plate 53, in the Z-axis direction.

If the optical path of a laser beam traveling toward the biaxial scanner14 is shifted, deviation of the irradiated position can be suppressedwhile changing the incident angle of the laser beam onto the screen 11by the operation of the concave surface formed on the biaxially movablemirror 20, similar to the first embodiment. As a result, the specklenoise can be reduced while preventing the quality of an image displayedon the screen 11 from lowering by concentrating laser beams on thescreen 11. In addition, although the parallel plate 53 is made to rockby the rocking device 56 in the third embodiment, the parallel plate 53may be made to rotate using a motor or the like.

Fourth Embodiment

FIG. 7 is a schematic view illustrating the configuration of an imagedisplay apparatus 100 according to a fourth embodiment of the invention.The fourth embodiment is characterized in that optical paths of laserbeams are shifted (converted) by return mirrors (return reflectionportions) 103 a, 103 b, and 103 c formed by dichroic mirrors. The sameconstituent components as in the first embodiment are denoted by thesame reference numerals, and a repeated explanation thereof will beomitted. Moreover, in the fourth embodiment, mixing of red (R) light,green (G) light, and blue (B) light will also be described.

The image display apparatus 100 is configured to include a light sourcedevice 102 a for B light, a light source device 102 b for G light, alight source device 102 c for R light, the return mirror 103 a for Blight, the return mirror 103 b for G light, the return mirror 103 c forR light, a biaxial scanner 14, and a vibrating device (incident positionchanging unit, return reflection portion moving unit) 106.

The light source device 102 a for B light, the light source device 102 bfor G light, and the light source device 102 c for R light (hereinafter,collectively referred to as light source devices for respective colors)are light source portions for emitting laser beams corresponding to B,G, and R colors which are coherent light. The laser beams are emittedfrom the light source device 102 a for B light toward the return mirror103 a for B light, from the light source device 102 b for G light towardthe return mirror 103 b for G light, and from the light source device102 c for R light toward the return mirror 103 c for R light. Since thelight source devices 102 a, 102 b, and 102 c for respective colors havethe same configuration as the light source device 12 described in thefirst embodiment except that colors of laser beams emitted arespecified, detailed explanations thereof will be omitted. In the fourthembodiment, the light source devices 102 a, 102 b, and 102 c forrespective colors are disposed such that laser beams emitted from thelight source devices 102 a, 102 b, and 102 c for respective colors areparallel.

The return mirror 103 a for B light, the return mirror 103 b for Glight, and the return mirror 103 c for R light (hereinafter,collectively referred to as return mirrors for respective colors) areformed by dichroic mirrors that make only light in a specific wavelengthrange reflected therefrom and light in the other wavelength rangetransmitted therethrough. The return mirror 103 a for B light reflects Blight therefrom. The return mirror 103 b for G light transmits the Blight therethrough and reflects G light therefrom. The return mirror 103c for R light transmits the G and B light therethrough and reflects Rlight therefrom. Each of the return mirrors 103 a, 103 b, and 103 c forrespective colors is formed such that a surface on which a laser beam isincident and a bottom surface are parallel. Furthermore, the returnmirrors 103 a, 103 b, and 103 c for respective colors are disposed inparallel such that top surfaces (bottom surfaces) thereof are parallel(hereinafter, a surface on which a laser beam emitted from each of thelight source devices 102 a, 102 b, and 102 c for respective colors isincident is referred to as a top surface and the opposite surface isreferred to as a bottom surface).

A laser beam emitted from the light source device 102 a for B light isreflected by the return mirror 103 a for B light. The reflectingdirection of the laser beam reflected by the return mirror 103 a for Blight is a direction traveling toward the return mirror 103 b for Glight.

A laser beam emitted from the light source device 102 b for G light isreflected by the return mirror 103 b for G light. The reflectingdirection of the laser beam reflected by the return mirror 103 b for Glight is a direction traveling toward the return mirror 103 c for Rlight.

The B light reflected by the return mirror 103 a for B light is incidenton a bottom surface of the return mirror 103 b for G light. Since thereturn mirror 103 b for G light reflects the G light therefrom, the Blight is not reflected but transmitted through the return mirror 103 bfor G light. The B light transmitted through the return mirror 103 b forG light travels through the return mirror 103 c for R light in parallelwith the G light reflected on a top surface of the return mirror 103 bfor G light.

The R light emitted from the light source device 102 c for R light isreflected by the return mirror 103 c for R light. The reflectingdirection of the laser beam reflected by the return mirror 103 c for Rlight is a direction traveling toward the biaxial scanner 14.

The G light reflected by the return mirror 103 b for G light and the Blight transmitted through the return mirror 103 b for G light areincident on a bottom surface of the return mirror 103 c for R light.Since the return mirror 103 c for R light reflects the R lighttherefrom, the G and B light is not reflected but transmitted throughthe return mirror 103 c for R light. The G and B light transmittedthrough the return mirror 103 c for R light travels through the biaxialscanner 14 in parallel with the R light reflected on a top surface ofthe return mirror 103 c for R light.

Since the biaxial scanner 14 has the same configuration as that in thefirst embodiment, a detailed explanation thereof will be omitted. Thevibrating device 106 is attached to each of the return mirrors 103 a,103 b, and 103 c for respective colors and vibrates (moves) each of thereturn mirrors 103 a, 103 b, and 103 c for respective colors in thenormal direction of the top surface. The vibrating device 106 has thepiezoelectric element 3 a and the like similar to the first embodiment,and a detailed explanation thereof will be omitted.

FIG. 8 is a schematic view illustrating optical paths of laser beamstransmitted through the return mirrors 103 a, 103 b, and 103 c forrespective colors Since each of the return mirrors 103 a, 103 b, and 103c for respective colors vibrates by an operation of the vibrating device106, a position of each of the return mirrors 103 a, 103 b, and 103 cfor respective colors at which a laser beam is reflected on the opticalpath of the laser beam changes. Accordingly, the optical path of thelaser beam reflected by each of the return mirrors 103 a, 103 b, and 103c for respective colors is shifted (converted) in the Z-axis direction.If the optical paths of laser beams traveling toward the biaxial scanner14 are shifted, the laser beams concentrate by the operation of theconcave surface formed in the biaxially movable mirror 20 so thatdeviation of the irradiated position can be suppressed, similar to thefirst embodiment. Accordingly, it is possible to prevent the quality ofan image displayed on the screen 11 from lowering. In addition, thespeckle noise can be reduced by changing the incident angle of a laserbeam onto the screen 11.

If the emission position of B light incident from the bottom surface ofthe return mirror 103 b for G light matches the reflection position of Glight, colors of the laser beams are mixed before reaching the screen11. Even if the incident position of a laser beam incident from thebottom surface of each of the return mirrors 103 a, 103 b, and 103 c forrespective colors does not match the reflection position of a laser beamon the top surface, colors of laser beams are mixed on the screen 11because these laser beams concentrate at approximately one point on thescreen 11. That is, it is not necessary to make the return mirrors 103a, 103 b, and 103 c for respective colors vibrate in synchronizationwith each other. In addition, even if the return mirrors 103 a, 103 b,and 103 c for respective colors are made to vibrate irregularly, laserbeams emitted from the light source devices 102 a, 102 b, and 102 c forrespective colors are mixed before reaching the screen 11 or at anypoint on the screen 11.

In addition, although the dichroic mirror is used as the return mirror103 a for B light in the fourth embodiment, a mirror that reflects lightin a wide wavelength range including B light may be used as the returnmirror 103 a for B light since there is no laser beam incident from thebottom surface of the return mirror 103 a for B light. Moreover, in thefourth embodiment, the light source devices 102 a, 102 b, and 102 c forrespective colors are disposed such that laser beams emitted from thelight source devices 102 a, 102 b, and 102 c for respective colors areparallel, the return mirrors 103 a, 103 b, and 103 c for respectivecolors are formed such that top and bottom surfaces thereof areparallel, and the return mirrors 103 a, 103 b, and 103 c for respectivecolors are disposed in parallel such that the top surfaces thereof areparallel. However, it is sufficient to configure the light sourcedevices 102 a, 102 b, and 102 c for respective colors and the returnmirrors 103 a, 103 b, and 103 c for respective colors such that laserbeams corresponding to respective colors are parallel when the laserbeams are incident on the concave surface, without being limited to thatdescribed above. For example, even if the top and bottom surfaces ofeach of the return mirrors 103 a, 103 b, and 103 c for respective colorsare not parallel, it is sufficient that light reflected on the topsurface and light emitted from the top surface are parallel.

Fifth Embodiment

FIG. 9 is a schematic view illustrating the configuration of an imagedisplay apparatus 150 according to a fifth embodiment of the invention.The same constituent components as in the first embodiment are denotedby the same reference numerals, and a repeated explanation thereof willbe omitted. Similar to the first embodiment, the process of mixing colorlight components of red (R) light, green (G) light, and blue (B) lightis also omitted. The fifth embodiment is characterized in that a concavesurface is formed of a different member from a scanning portion.

The image display apparatus 150 is configured to include a light sourcedevice 12, a return mirror (concave reflection portion, returnreflection portion) 153, a vibrating device (incident position changingunit, return reflection portion moving unit) 155, and a biaxial scanner(scanning portion) 154. Since the light source device 12 has the sameconfiguration as that in the first embodiment, a detailed explanationthereof will be omitted.

The return mirror 153 reflects a laser beam emitted from the lightsource device 12 toward the biaxial scanner 154. The return mirror 153is disposed on the optical path of the laser beam emitted from the lightsource device 12, and a reflecting surface 153 a from which the laserbeam is reflected is a cylindrical concave surface.

The vibrating device 155 vibrates (moves) the return mirror 153. Thevibrating device 155 is attached to the end of the return mirror 153.The vibrating device 155 has a piezoelectric element 3 a similar to thefirst embodiment, and the return mirror 153 vibrates by repeatedapplication of a voltage to the piezoelectric element 3 a. The vibrationdirection of the return mirror 153 by the operation of the vibratingdevice 155 is a direction (Y-axis direction) approximately perpendicularto the optical path of a laser beam emitted from the light source device12.

FIG. 10 is a schematic view illustrating optical paths of laser beamsreflected by the return mirror 153. Due to vibration of the returnmirror 153, the incident position of a laser beam onto the reflectingsurface 153 a and the position at which the optical path of a laser beamis cut by the reflecting surface 153 a change. Accordingly, the opticalpaths after reflection are shifted in the Z-axis direction by vibrationof the return mirror 153. In addition, since the reflected surface is aconcave surface, the optical paths are concentrated eventually.

Although the biaxial scanner 154 has approximately the sameconfiguration as the biaxial scanner 14 in the first embodiment, thebiaxial scanner 154 is different from the biaxial scanner 14 in thefirst embodiment in that a reflecting surface 160 a of a biaxiallymovable mirror 160 is not a concave surface but a flat surface. Thelaser beam reflected by the return mirror 153 is further reflected on areflecting surface of the biaxially movable mirror 160 to move towardthe screen 11.

Therefore, similar to the first embodiment, it is possible to preventthe image quality from lowering by suppressing deviation of theirradiated position by concentration of laser beams and to reduce aspeckle noise by changing the incident angle of a laser beam onto thescreen 11.

In the fifth embodiment, the reflecting surface 153 a which is a concavesurface is formed on the return mirror 153 that moves linearly.Accordingly, compared with a case where a concave surface is formed on amember (for example, a scanning portion) that rotates or rocks,distortion of the concave surface caused by the moment can besuppressed. As a result, since it becomes easy to concentrate laserbeams on the screen 11 with high precision, a high-quality image can bedisplayed for a viewer.

Moreover, in the fifth embodiment, the incident position of a laser beamonto the reflecting surface 153 a is changed by vibrating the returnmirror 153 formed with the concave surface. However, the invention isnot limited thereto, but the incident position of a laser beam may alsobe changed by vibrating the light source device or by additionallyproviding a parallel plate and rocking the parallel plate as shown inFIG. 5.

Sixth Embodiment

FIG. 11 is a schematic view illustrating the configuration of an imagedisplay apparatus 200 according to a sixth embodiment of the invention.The same constituent components as in the first embodiment are denotedby the same reference numerals, and a repeated explanation thereof willbe omitted. Similar to the first embodiment, the process of mixing colorlight components of red (R) light, green (G) light, and blue (B) lightis also omitted. The image display apparatus 200 according to the sixthembodiment is characterized in that a scanning portion is configured toinclude a horizontal scanning mirror (first scanning portion) 202 and avertical scanning mirror (second scanning portion) 204 and a reflectingsurface 204 a of the vertical scanning mirror 204 is a concave surface.

The image display apparatus 200 is configured to include a light sourcedevice 12, a vibrating device (incident position changing unit) 13, thehorizontal scanning mirror 202, and the vertical scanning mirror 204.Since the light source device 12 has the same configuration as that inthe first embodiment, a detailed explanation thereof will be omitted.The vibrating device 13 has the same configuration as that in the secondembodiment and shifts an optical path of a laser beam incident on thereflecting surface 204 a in the curvature direction (Z-axis direction)of the reflecting surface 204 a.

The horizontal scanning mirror 202 reflects the laser beam emitted fromthe light source device 12 toward the vertical scanning mirror 204.Furthermore, the horizontal scanning mirror 202 has a function ofrocking around the Y axis to thereby scan a laser beam in the horizontaldirection (first direction).

The vertical scanning mirror 204 makes the laser beam, which has beenreflected by the horizontal scanning mirror 202, further reflectedtoward the screen 11. Furthermore, the vertical scanning mirror 204 hasa function of rocking around the X axis to thereby scan a laser beam inthe vertical direction (second direction). Since the horizontal scanningmirror 202 and the vertical scanning mirror 204 cooperate to scan laserbeams in the horizontal and vertical directions, a two-dimensional imagecan be displayed on the screen 11.

A cylindrical concave surface is formed on the reflecting surface 204 aof the vertical scanning mirror 204. Since laser beams incident on thereflecting surface 204 a are shifted in the curvature direction (Z-axisdirection) by the operation of the vibrating device 13, the incidentpositions of laser beams onto the reflecting surface 204 a also change.Since the concave surface is formed on the reflecting surface 204 a, thelaser beams are concentrated eventually even if the incident positionsof the laser beams are different. Therefore, similar to the firstembodiment, it is possible to prevent the image quality from lowering bysuppressing deviation of the irradiated position by concentration oflaser beams and to reduce a speckle noise by changing the incident angleof a laser beam onto the screen 11.

In the sixth embodiment, a rocking period of the vertical scanningmirror 204 is longer than that of the horizontal scanning mirror 202.For example, when the number of pixels of an image displayed is 1024pixels in the horizontal direction and 768 pixels in the verticaldirection, the horizontal scanning mirror 202 scans a laser beam 1024times in the horizontal direction while the vertical scanning mirror 204scans a laser beam once in the vertical direction. Since a concavesurface is formed on the reflecting surface 204 a of the verticalscanning mirror 204 that rocks at lower speed than the horizontalscanning mirror 202, there is little influence of the moment applied tothe concave surface. Accordingly, concentration of laser beams on thescreen 11 can be performed with high precision.

When the scanning portion is configured to be divided into the firstscanning portion rocking in a first direction (for example, horizontaldirection) and the second scanning portion rocking in a second direction(for example, vertical direction approximately perpendicular to thefirst direction) like the sixth embodiment, the incident position of alaser beam onto the second scanning portion changes with rocking of thefirst scanning portion. Accordingly, in case of forming a concavesurface on the second scanning portion, the angle of reflection of alaser beam scanned by the first scanning portion on the second scanningportion is influenced by the curvature when the curvature direction ofthe concave surface and the first direction are parallel. Since theangle of reflection of a laser beam on the second scanning portion isinfluenced by the curvature, it becomes difficult to control thescanning position of the laser beam. As a result, an image displayed onthe screen 11 is easily distorted. For this reason, in case of forming aconcave surface on the second scanning portion, it is desirable to setthe curvature direction of the concave surface as a directionapproximately perpendicular to the first direction.

Moreover, in the sixth embodiment, the incident position of a laser beamonto the concave surface is changed by vibrating the light source device12. However, the invention is not limited thereto, but the incidentposition of a laser beam may also be changed by additionally providing areturn mirror and vibrating the return mirror as shown in FIG. 1 or byadditionally providing a parallel plate and rocking the parallel plateas shown in FIG. 5

Seventh Embodiment

FIG. 12 is a schematic view illustrating the configuration of an imagedisplay apparatus 250 according to a seventh embodiment of theinvention. The same constituent components as in the first embodimentare denoted by the same reference numerals, and a repeated explanationthereof will be omitted. Similar to the first embodiment, the process ofmixing color light components of red (R) light, green (G) light, andblue (B) light is also omitted. The image display apparatus 250according to the seventh embodiment is characterized in that a scanningportion is configured to include a horizontal scanning mirror (firstscanning portion) 252 and a vertical scanning mirror (second scanningportion) 254 and a reflecting surface 252 a of the horizontal scanningmirror 252 is a concave surface.

The image display apparatus 250 is configured to include a light sourcedevice 12, a vibrating device (incident position changing unit) 13, thehorizontal scanning mirror 252, and the vertical scanning mirror 254.Since the light source device 12 has the same configuration as that inthe first embodiment, a detailed explanation thereof will be omitted.The vibrating device 13 has the same configuration as that in the secondembodiment and shifts an optical path of a laser beam, which is emittedfrom the light source device 12, in the curvature direction (Y-axisdirection) of the reflecting surface 252 a which will be describedlater.

The horizontal scanning mirror 252 reflects the laser beam emitted fromthe light source device 12 toward the vertical scanning mirror 254.Furthermore, the horizontal scanning mirror 252 has a function ofrocking around the Y axis to thereby scan a laser beam in the horizontaldirection.

The vertical scanning mirror 254 makes the laser beam, which has beenreflected by the horizontal scanning mirror 252, further reflectedtoward the screen 11. Furthermore, the vertical scanning mirror 254 hasa function of rocking around the X axis to thereby scan a laser beam inthe vertical direction. Since the horizontal scanning mirror 252 and thevertical scanning mirror 254 cooperate to scan laser beams in thehorizontal and vertical directions, a two-dimensional image can bedisplayed on the screen 11.

A cylindrical concave surface is formed on the reflecting surface 252 aof the horizontal scanning mirror 252. Since laser beams incident on thereflecting surface 252 a are shifted in the curvature direction (Y-axisdirection) by the operation of the vibrating device 13, the incidentpositions of laser beams onto the reflecting surface 252 a also change.Since the concave surface is formed on the reflecting surface 252 a, thelaser beams are concentrated eventually even if the incident positionsof the laser beams are different. Therefore, similar to the firstembodiment, it is possible to prevent the image quality from lowering bysuppressing deviation of the irradiated position by concentration oflaser beams and to reduce a speckle noise by changing the incident angleof a laser beam onto the screen 11.

In the seventh embodiment, a rocking period of the horizontal scanningmirror 252 is shorter than that of the vertical scanning mirror 254. Forexample, when the number of pixels of an image displayed is 1024 pixelsin the horizontal direction and 768 pixels in the vertical direction,the horizontal scanning mirror 252 scans a laser beam 1024 times in thehorizontal direction while the vertical scanning mirror 254 scans alaser beam once in the vertical direction. The horizontal scanningmirror 252 rocking at higher speed than the vertical scanning mirror 254is formed by a small member (for example, a MEMS mirror) in many cases.Since the horizontal scanning mirror 252 is small, the concave surfaceformed on the reflecting surface 252 a is also small. Since the concavesurface is small, an influence (for example, variation in the reflectingdirection) caused by making the reflecting surface 252 a have thecurvature can be suppressed. As a result, distortion of an imagedisplayed on an irradiated surface can be reduced irrespective of thecurvature direction of the concave surface.

Moreover, in the seventh embodiment, the incident position of a laserbeam onto the concave surface is changed by vibrating the light sourcedevice 12. However, the invention is not limited thereto, but theincident position of a laser beam may also be changed by additionallyproviding a return mirror and vibrating the return mirror as shown inFIG. 1 or by additionally providing a parallel plate and rocking theparallel plate as shown in FIG. 5.

Eighth Embodiment

FIG. 13 is a schematic view illustrating the configuration of an imagedisplay apparatus 300 according to an eighth embodiment of theinvention. The same constituent components as in the first embodimentare denoted by the same reference numerals, and a repeated explanationthereof will be omitted. Similar to the first embodiment, the process ofmixing color light components of red (R) light, green (G) light, andblue (B) light is also omitted. The image display apparatus 300according to the eighth embodiment is characterized in that a scanningportion is configured to include a horizontal scanning mirror (firstscanning portion) 302, a vertical scanning mirror (second scanningportion) 304, and a return mirror within a scanning portion (concavereflection portion, return reflection portion within a scanning portion)306 and the return mirror within a scanning portion 306 formed with areflecting surface 306 a as a concave surface is disposed on the opticalpath between the horizontal scanning mirror 302 and the verticalscanning mirror 304.

The image display apparatus 300 is configured to include a light sourcedevice 12, a vibrating device (incident position changing unit) 13, thehorizontal scanning mirror 302, the return mirror within a scanningportion 306, and the vertical scanning mirror 304. Since the lightsource device 12 has the same configuration as that in the firstembodiment, a detailed explanation thereof will be omitted. Thevibrating device 13 has the same configuration as that in the secondembodiment and shifts an optical path of a laser beam, which is emittedfrom the light source device 12, in the curvature direction (Y-axisdirection) of the reflecting surface 306 a which will be describedlater.

The horizontal scanning mirror 302 reflects the laser beam emitted fromthe light source device 12 toward the return mirror within a scanningportion 306. The horizontal scanning mirror 302 has a function ofrocking around the Y axis to thereby scan a laser beam in the horizontaldirection.

The return mirror within a scanning portion 306 makes the laser beam,which has been reflected by the horizontal scanning mirror 302, furtherreflected toward the vertical scanning mirror 304. A cylindrical concavesurface is formed on the reflecting surface 306 a of the return mirrorwithin a scanning portion 306. Since laser beams incident on thereflecting surface 306 a are shifted in the curvature direction (Y-axisdirection) by the operation of the vibrating device 13, the incidentpositions of laser beams onto the reflecting surface 306 a also change.Since the concave surface is formed on the reflecting surface 306 a, thelaser beams are concentrated eventually even if the incident positionsof the laser beams are different. Therefore, similar to the firstembodiment, it is possible to prevent the image quality from lowering bysuppressing deviation of the irradiated position by concentration oflaser beams and to reduce a speckle noise by changing the incident angleof a laser beam onto the screen 11.

The vertical scanning mirror 304 makes the laser beam, which has beenreflected by the return mirror within a scanning portion 306, reflectedtoward the screen 11. The vertical scanning mirror 304 has a function ofrocking around the X axis to thereby scan a laser beam in the verticaldirection. Since the horizontal scanning mirror 302 and the verticalscanning mirror 304 cooperate to scan laser beams in the horizontal andvertical directions, a two-dimensional image can be displayed on thescreen 11.

In the eighth embodiment, the concave surface is formed on the returnmirror within a scanning portion 306 which is not related to scanning oflaser beams, that is, which does not perform a rocking operation. Sincethe return mirror within a scanning portion 306 does not rock, theconcave surface is not bent by the moment. Accordingly, since it can beprevented that coherent light is dispersed by bending of the concavesurface, it is possible to prevent the display quality from lowering.

A larger member than the horizontal scanning mirror 302 or the verticalscanning mirror 304 is used as the return mirror within a scanningportion 306, which is not related to scanning of coherent light, in manycases. As a result, since it becomes easy to form a concave surface onthe return mirror within a scanning portion 306, the manufacturing costcan be suppressed.

When the scanning portion is configured to include the first scanningportion that scans a laser beam in a first direction (for example,horizontal direction), the second scanning portion that scans a laserbeam in a second direction (for example, vertical directionapproximately perpendicular to the first direction), and the returnmirror within a scanning portion disposed on the optical path betweenthe first and second scanning portions like the eighth embodiment, theincident position of a laser beam onto the return mirror within ascanning portion changes by rocking of the first scanning portion.Accordingly, in case of forming a concave surface on the return mirrorwithin a scanning portion, the angle of reflection of a laser beamscanned by the first scanning portion on the return mirror within ascanning portion is influenced by the curvature when the curvaturedirection of the concave surface and the first direction are parallel.Since the angle of reflection of a laser beam on the return mirrorwithin a scanning portion is influenced by the curvature, it becomesdifficult to control the irradiated position of the laser beam. As aresult, an image displayed on the screen 11 is easily distorted. Forthis reason, in case of forming a concave surface on the return mirrorwithin a scanning portion disposed between the first and second scanningportions, it is desirable to set the curvature direction of the concavesurface as a direction approximately perpendicular to the firstdirection.

Compared with the eighth embodiment, the return mirror within a scanningportion is not required between the first and second scanning portionsin the sixth and seventh embodiments. Accordingly, since the number ofconstituent components can be reduced in the sixth and seventhembodiments, the manufacturing cost can be suppressed and the space canbe saved.

Moreover, in the eighth embodiment, the incident position of a laserbeam onto the concave surface is changed by vibrating the light sourcedevice 12. However, the invention is not limited thereto, but theincident position of a laser beam may also be changed by additionallyproviding a return mirror and vibrating the return mirror as shown inFIG. 1 or by additionally providing a parallel plate and rocking theparallel plate as shown in FIG. 5.

The entire disclosure of Japanese Patent Application No. 2008-94757,filed Apr. 1, 2008 is expressly incorporated by reference herein.

1. An image display apparatus that displays an image by scanning ofcoherent light, comprising: a light source portion that emits thecoherent light; a scanning portion that scans the coherent light emittedby the light source portion; a concave reflection portion having aconcave surface from which the coherent light scanned by the scanningportion is reflected; an incident position changing unit that changes anincident position of the coherent light onto the concave surface in acurvature direction of the concave surface; and a return reflectionportion that reflects the coherent light to travel to the scanningportion, wherein the scanning portion includes the concave reflectionportion, and the incident position changing unit is a return reflectionportion moving unit that moves the return reflection portion.
 2. Theimage display apparatus according to claim 1, wherein the incidentposition changing unit is a light source moving unit that moves thelight source portion.
 3. The image display apparatus according to claim1, further comprising: a transmission portion that is disposed on anoptical path of the coherent light before being incident on the concavesurface and that transmits the coherent light therethrough, wherein theincident position changing unit is an inclination changing unit thatchanges the inclination of the transmission portion with respect to thecoherent light.
 4. The image display apparatus according to claim 1,wherein the return reflection portion is a dichroic mirror.
 5. The imagedisplay apparatus according to claim 1, wherein the scanning portion hasa first scanning portion, which scans the coherent light in a firstdirection, and a second scanning portion, which scans the coherent lightin a second direction approximately perpendicular to the first directionat a longer period than a period at which the coherent light is scannedby the first scanning portion, and the second scanning portion includesthe concave reflection portion.
 6. The image display apparatus accordingto claim 1, wherein the scanning portion has a first scanning portionthat scans the coherent light in a first direction, a second scanningportion that scans the coherent light in a second directionapproximately perpendicular to the first direction, and a returnreflection portion within a scanning portion that reflects the coherentlight reflected by the first scanning portion toward the second scanningportion, and the return reflection portion within a scanning portionincludes the concave reflection portion.
 7. The image display apparatusaccording to claim 5, wherein the first direction and the curvaturedirection of the concave surface are approximately perpendicular to eachother.
 8. The image display apparatus according to claim 1, wherein thescanning portion has a first scanning portion, which scans the coherentlight in a first direction, and a second scanning portion, which scansthe coherent light in a second direction approximately perpendicular tothe first direction at a longer period than a period at which thecoherent light is scanned by the first scanning portion, and the firstscanning portion includes the concave reflection portion.
 9. The imagedisplay apparatus according to claim 1, further comprising: a returnreflection portion that reflects the coherent light to travel to thescanning portion, wherein the return reflection portion includes theconcave reflection portion, and the incident position changing unit is areturn reflection portion moving unit that moves the return reflectionportion.